Project description:The cerebral cortex develops from dorsal forebrain neuroepithelial progenitor cells. Initial expansion of the progenitor cell pool is followed by the generation of neurons of all the cortical layers and later, astrocytes and oligodendrocytes. However, the regulatory pathways that control the expansion and maintenance of the neuroepithelial progenitor cell pool are currently unknown. Here we define six basic pathway components that regulate proliferation of cortically specified human neuroepithelial stem cells (cNESCs) in vitro without the loss of developmental potential. We show that activation of FGF and inhibition of BMP and ACTIVIN A signalling are required for long-term cNESC proliferation. We also demonstrate that cNESCs preserve dorsal telencephalon-specific potential when GSK3, AKT and nuclear CATENIN-b1 activity are low. Remarkably, regulation of these six pathway components supports the clonal expansion of cNESCs. Moreover, cNESCs differentiate to lower and upper layer cortical neurons both in vitro and in vivo. Identifying the mechanisms that drive the self-renewal and fate of cNESCs decision of neuroepithelial stem cells is key to developing new stem cell-based therapeutic approaches to treat neurological conditions.

Project description:The NSC differentiation of six validated iPSC lines were induced using commercially available PSC neural induction medium and following manufacturer method with minor modifications (Gibco). An extensive characterization of generated NSCs on day 14 (at passage P1) was performed using immunocytochemistry (ICC) analysis of the NSC specific markers and by genome wide mRNA sequencing. The iPSC differentiated NSCs expressed NSC specific markers Nestin, PAX6, SOX1 and SOX2 across all six samples. The average correlation coefficient at 95% CI between 6 NSC samples, calculated based on all expressed mRNAs, was 0.97 ± 0.008 suggesting a uniform differentiation of generated NSC lines. The generated NSC showed high expression of neuroepithelial genes/transcription factors (NES, SOX2, SOX1, PAX6, NOTCH1, MSI1,and CHD2) and genes/transcription factors of dorsal tube neuroepithelium (PAX3, GDF7, SOX9 and SNAI2) but lacked the expression of ventral tube neuroepithelial markers (NKX2-2, FOXA2 and SHH) suggesting a dorsal tube neuroepithelial transcriptomic and functional profile of the generated NSCs. A differential gene expression analysis of iPSC’s and NSC’s expressed transcription identified 4,033 mRNAs that were significantly differentially expressed (DE) between iPSCs and differentiated NSCs. The 2,006 DE mRNA were significantly upregulated in differentiated NSCs and were highly enriched in developmental functional categories such as embryonic development (572 mRNAs; FDR adjusted p-value range: 1.92x10-53 – 3.26x10-9), organism development (749 mRNAs; FDR adjusted p-value range: 1.92x10-53 – 4.30x10-9), nervous system development and function (629 mRNAs; FDR adjusted p-value range: 3.23x10-48 – 4.15x10-9), tissue development (655 mRNAs; FDR adjusted p-value range: 3.63x10-40 – 4.32x10-9) and organ development (406 mRNAs; FDR adjusted p-value range: 8.74x10-40 – 2.37x10-9).

Project description:Developing a model of primate neural tube (NT) development is important to promote many NT disorder studies in model organisms. Here, we report a robust and stable system to allow for clonal expansion of single monkey neuroepithelial stem cells (NESCs) to develop into miniature NT-like structures. Single NESCs can produce functional neurons in vitro, survive and extensively regenerate neuron axons in monkey brain. NT formation and NESC maintenance depend on high metabolism activity and Wnt signaling. NESCs are regionally restricted into a telencephalic fate. Moreover, single NESCs can turn into radial glial progenitors (RGPCs). The transition is accurately regulated by Wnt signaling through regulation of Notch signaling and adhesion molecules. Finally, using the â??NESC-TO-NTsâ?? system, we model the functions of folic acid (FA) on NT closure and demonstrate FA can regulate multiple mechanisms to prevent NT defects. Together, our system is ideal for studying NT development and diseases. compare gene expression profiles in monkey neuroepithelial stem cells (NESCs), newly converted radial glial progenitor cells (RPGCs) from NESCs and differentiated neurons from NESCs

Project description:To interrogate the alternative fates of pancreas and liver in the earliest stages of human organogenesis, we developed laser capture, RNA amplification, and computational analysis of deep sequencing. Pancreas-enriched gene expression was less conserved between human and mouse than for liver. The dorsal pancreatic bud was enriched for components of Notch, Wnt, BMP, and FGF signaling, almost all genes known to cause pancreatic agenesis or hypoplasia, and over 30 unexplored transcription factors. SOX9 and RORA were imputed as key regulators in pancreas compared with EP300, HNF4A, and FOXA family members in liver. Analyses implied that current in vitro human stem cell differentiation follows a dorsal rather than a ventral pancreatic program and pointed to additional factors for hepatic differentiation. In summary, we provide the transcriptional codes regulating the start of human liver and pancreas development to facilitate stem cell research and clinical interpretation without inter-species extrapolation.

Project description:Long noncoding RNAs (lncRNAs) have emerged as important components of gene regulatory network in embryonic stem cells (ESCs). However, the function and molecular mechanism of lncRNAs are still largely unknown. Here we identified Trincr1 (TRIM71 interacting long noncoding RNA 1) lncRNA that regulates the FGF/ERK signaling and self-renewal of ESCs. Trincr1 is exported by THOC complex to cytoplasm where it binds and represses TRIM71, leading to the downregulation of SHCBP1 protein. Knocking out Trincr1 leads to the upregulation of phosphorylated ERK and ERK pathway target genes and the decrease of ESC self-renewal, while knocking down Trim71 completely rescues the defects of Trincr1 knockout. Furthermore, ectopic expression of Trincr1 represses FGF/ERK signaling and the self-renewal of neural progenitor cells. Together, this study reveals more regulators in FGF/ERK signaling pathway and highlights lncRNA as an important player in cell signaling network to coordinate cell fate specification.

Project description:Small hepatocyte-like progenitor cells (SHPCs) are hepatocytic progenitor cells that transiently form clusters in rat livers treated with retrorsine and with 70% partial hepatectomy (PH). We previously reported that transplantation of Thy1+ cells derived from D-galactosamine-treated livers promotes SHPC expansion, resulting in the acceleration of liver regeneration. Extracellular vesicles (EVs) produced by Thy1+ cells act on sinusoidal endothelial cells (SECs) and Kupffer cells to secrete IL17B and IL25, respectively, resulting in SHPC activation through IL17 receptor B (RB) signaling. Our aim is to identify factors in Thy1-EVs that activate IL17RB signaling. Thy1+ cells isolated from rats with D-galactosamine-induced liver injury were cultured for one week. Although some liver stem/progenitor cells proliferated into colonies, others maintained as mesenchymal cells (MCs). Thy1-MCs or Thy1-liver stem/progenitor cells were transplanted into retrorsine/PHtreated livers to examine their effects on SHPCs. SHs isolated from adult rat livers were used to validate factors regulating growth induction. The number and size of SHPCs remarkably increased in livers transplanted with Thy1-MCs. Comprehensive analysis of Thy1-MC-EVs revealed that miR-199a-5p, CINC-2, and MCP-1 are candidates for stimulating SHPC growth. Administration of the miR-199a-5p mimic, and not CINC-2, promoted SH growth. SECs treated with CINC-2 induced IL17b expression and their conditioned medium promoted SH growth. Thy1-MC transplantation may accelerate liver regeneration due to SHPCs expansion, which is stimulated by CINC-2/IL17RB signaling and miR-199a-5p.

Project description:Undifferentiated spermatogonia comprise a pool of stem cells and progenitor cells that show heterogeneous expression of markers, including the cell surface receptor GFRα1. Technical challenges in isolation of GFRα1+ versus GFRα1- undifferentiated spermatogonia have precluded the comparative molecular characterization of these subpopulations and their functional evaluation as stem cells. Here, we develop a method to purify these subpopulations by FACS and show that GFRα1+ and GFRα1- undifferentiated spermatogonia both demonstrate elevated transplantation activity while differing principally in receptor tyrosine kinase signaling and cell cycle. We identify the cell surface molecule MCAM as differentially expressed in these populations and show that antibodies to MCAM allow isolation of highly enriched populations of GFRα1+ and GFRα1- spermatogonia from adult, wild-type mice. In germ cell culture, GFRα1- cells upregulate MCAM expression in response to GDNF/FGF stimulation. In transplanted hosts, GFRα1- spermatogonia yield GFRα1+ spermatogonia and restore spermatogenesis, albeit at lower rates than their GFRα1+ counterparts. Together, these data provide support for a model of a stem cell pool in which the GFRα1+ and GFRα1- cells are closely related, but show key cell-intrinsic differences and can interconvert between the two states based, in part, on access to niche factors.

Project description:Cord blood hematopoietic stem cells (CB-HSCs) are an outstanding source for transplantation approaches. However, the amount of cells per donor is limited and culture expansion of CB-HSCs is accompanied by a loss of engraftment potential. In order to analyze the molecular mechanisms leading to this impaired potential we profiled global and local epigenotypes during the expansion of human CB hematopoietic stem and progenitor cells (HPSCs). Human CB-derived CD34+ cells were cultured in serum-free medium together with SCF, TPO, FGF, with or without Igfbp2 and Angptl5 (STF/STFIA cocktails). As compared to the STF cocktail, the STFIA cocktail maintains in vivo repopulation capacity of cultured CD34+ cells. Upon expansion, CD34+ cells genome-wide remodel their epigenotype and depending on the cytokine cocktail, cells show different H3K4me3 and H3K27me3 levels. Expanding cells without Igfbp2 and Angptl5 leads to higher global H3K27me3 levels. ChIPseq analyses reveal a cytokine cocktail-dependent redistribution of H3K27me3 profiles. Inhibition of the PRC2 component EZH2 counteracts the culture-associated loss of NOD scid gamma (NSG) engraftment potential. Collectively, our data reveal chromatin dynamics that underlie the culture-associated loss of engraftment potential. We identify PRC2 component EZH2 as being involved in the loss of engraftment potential during the in vitro expansion of HPSCs. 6 samples were hybridized GeneChip Human Gene 1.0 ST Arrays (Affymetrix)

Project description:In the mammalian neocortex, diverse projection neuron types are generated by the same pool of neural progenitors in sequential waves. How neuronal cell type specification is related to developmental timing remains unclear. To determine whether neural progenitor cell heterogenity correlates with neuronal type spcification, we performed single cell RNA sequencing analysis of the developing mouse neocortex (E10.5 through E18.5) by Drop-Seq. We uncovered cellular and molecular diversity among neuroepithelial cells, radial glial cells, intermediate progenitors and neuron types.

Project description:A single normal hematopoietic stem cell (HSC) is sufficient to regenerate the entire blood system after bone marrow transplantation. This process requires not only rapid mobilization of the stem cell into the cell cycle, but also the proliferation of committed progenitor cells to provide functional mature cells until HSC progeny have accumulated to sufficient numbers1. Gene disruption strategies have dissected the regulatory pathways and identified critical factors that mediate the decision of a stem cell to self-renew and quiesce or to enter the rapidly expanding progenitor cell pool to populate the various hematopoietic cell lineages. However, only a very limited number of the transcriptional regulators and chromatin remodeling factors that are recruited by DNA binding factors have been pinpointed as contributors to stem cell functions. Here, we show that the transcriptional co-repressor Myeloid Translocation Gene on chromosome 16 (Mtg16), which is targeted by the t(16;21) in acute myeloid leukemia, is required for long-term hematopoietic stem cell functions and suppression of stem cell mobilization. Although there are no dramatic defects in the allocation of cells to any of the major hematopoietic cell lineages, inactivation of Mtg16 impairs the rapid expansion of stem/progenitor cells, which is required after bone marrow transplantation. This impairment appears to be a failure to proliferate rather than an induction of cell death, as expression of c-Myc complements the Mtg16-/- defect. Keywords: Knock-out analysis, genetic modification